• Korean Journal of Poultry Science
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• v.11 no.2
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• pp.109-114
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• 1984

The experiment was made to study the effect of levels of metabolizable energy of basal diets on apparent metabolizable energy (AME) and true metabolizable energy (TME) values of corn and soybean meals. The test materials, corn and soybean meals, were substituted with basal diet at 50% and 30%, respectively. The excreta of fed md unfed birds were collected for 30 hours. The results obtained were as follows; 1. The AME values of corn were not significantly different among treatments (P＞0.05) except for 2400 Kcal/13% treatment, The AME values of soybean meals differed significantly between 2,400 Kcal/13% and 2,800 Kcal/15% or 3,000 Kcal/16%, but were not different between 2,400 Kcal/13% and 2,600 Kcal/14 % (probability at 5% level). 2. The energy levels of basal diets did not affect the AME values of corn and soybean meals (P＞0.05) except 2,400 Kcal/13% treatment. This fact indicates that it is not necessary to change energy levels of basal diet according to test materials. 3. That the values of standard error of soybean meals were higher than those of corn was resulted from its low level of substitution with basal diet. 4. The TME values of corn showed significant differences (P＜0.05) between 2,400Kcal/13% treatment and other treatments but those of soybean meals were not different among all treatments (P＞0.05). 5. The reason that the AME values of corn and soybean meals and the TME values of corn reduced significantly in 2,400 Kcal/13% could be explained by the effect of interaction among ingredients in the diet.

• Asian-Australasian Journal of Animal Sciences
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• v.9 no.5
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• pp.571-575
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• 1996

An experiment was conducted to measure the true metabolizable energy (TME) values of seven major poultry feed ingredients, two feed concentrates and one randomly collected layer mixed feed prepared from the available feed ingredients. The results of this study were the most thorough evaluation of the TME content of some selected common feed ingredients of Bangladesh. The observed TME values of some feed ingredients were very close to the values of different origins of feed ingredients. But the TME values measured in mixed layer feed were very low which could not support the standard requirement of laying birds. There values will be of assistance in describing the energy content of the most common available feed ingredients of Bangladesh.

• Asian-Australasian Journal of Animal Sciences
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• v.31 no.4
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• pp.564-568
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• 2018

Objective: This experiment was conducted to determine the effects of dietary ${\beta}$-mannanase on the additivity of true metabolizable energy (TME) and nitrogen-corrected true metabolizable energy ($TME_n$) for broiler diets. Methods: A total of 144 21-day-old broilers were randomly allotted to 12 dietary treatments with 6 replicates. Five treatments consisted of 5 ingredients of corn, wheat, soybean meal, corn distillers dried grains with solubles, or corn gluten meal. One mixed diet containing 200 g/kg of those 5 ingredients also was prepared. Additional 6 treatments were prepared by mixing 0.5 g/kg dietary ${\beta}$-mannanase with those 5 ingredients and the mixed diet. Based on a precision-fed chicken assay, TME and $TME_n$ values for 5 ingredients and the mixed diet as affected by dietary ${\beta}$-mannanase were determined. Results: Results indicated that when ${\beta}$-mannanase was not added to the diet, measured TME and $TME_n$ values for the diet did not differ from the predicted values for the diet, which validated the additivity. However, for the diet containing ${\beta}$-mannanase, measured $TME_n$ value was greater (p<0.05) than predicted $TME_n$ value, indicating that the additivity was not validated. Conclusion: In conclusion, the additivity of energy values for the mixed diet may not be guaranteed if the diet contains ${\beta}$-mannanase.

• Asian-Australasian Journal of Animal Sciences
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• v.17 no.4
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• pp.514-517
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• 2004

Expeller pressed and solvent extracted palm kernel cake (PKC) were force-fed to male and female Muscovy ducks at 7 weeks of age. The nutrient digestibility, apparent metabolizable energy (AME), true metabolizable energy (TME) and true available amino acid (TAAA) digestibilities were determined. There was no significant (p>0.05) effect of the type of PKC used on crude protein (CP), ether extract (EE), metabolizable energy (ME) and amino acid (AA) digestibilities. However, digestibilities of dry matter (DM) and neutral detergent fibre (NDF) was found to be higher in solvent extracted compared to expeller pressed PKC. The average digestibility of DM, CP, NDF and EE were 43, 58, 39 and 89%, espectively. It was found that the ducks utilized about 47% of the gross energy of PKC. The respective average AMEn and TMEn values of PKC for Muscovy ducks was 1,743 and 1,874 kcal/kg. The overall TAAA of PKC for Muscovy ducks was 65%. The data on the TMEn and digestible AA for PKC obtained from this study provide new information with regard to diet formulation for Muscovy ducks.

• Korean Journal of Poultry Science
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• v.11 no.2
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• pp.99-108
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• 1984

The experiment was performed with the aim to study not only the effect of protein levels of basal diets on apparent and true metabolizable energy (AME and THM), AME of Farrell(AME$\_$F/), and corrected AME$\_$FC/ values of corn and soybean meal but also the effect of collection time of excreta on AME and TME values of corn and soybean meal. The AME$\_$F/ and AME$\_$FC/ values of test materials were determined through rapid AME bioassay, and AME and TME by the TME bioassay. The protein levels of basal diets had range from 10% crude protein(CP) to 30% CP. The results obtained were as follows; 1. The AME$\_$F/ values of basal diets showed much difference among treatments (P＜0.05) but those of corn and soybean meal had no significant differences (P＞0.05)and the AHE$\_$FC/ values of basal diets were proved to be variable according to level of protein of the diets. the AME$\_$FC/ values of com were not different while those of soybean meal in 20% and 30% were reduced significantly(P＜0.05). 2. The protein intake/bird/day did not differ significantly due to variation of feed intake using rapid AME bioassay. 3. The protein levels of basal diets did not influence upon the AME value of basal diets, corn and soybean meal (P＞0.05), and no clear trend was found in the TME values of corn and soybean meal because of the variation of metabolic fecal energy plus endogenous urinary energy (FEm＋UEe) losses fed different diets. 4. Collection time of excreta affected the AME and TME values of basal diets in 10, 15, 20% CP treatments, but the AME and TME of corn and soybean meal were not affected by collection time; Thus, a time of 24 hours was mough for 24 hr to clean the digestive tract when fed corn and soybean meal substituted diets regardless of protein levels.

• Korean Journal of Poultry Science
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• v.7 no.2
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• pp.4-17
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• 1980

This is to review from the existing literatures the various methods of determination, problems involved in the determination of metabolizable energy(ME) values of poultry feedstuffs that is the most widely used energy term in poultry nutrition. An attempt will also be made to introduce the newly developed determination method of ME by Sibbald and his associates. It was found that conventional methods of ME measurements such as total collection method and indicator method require a great deal of labor and time. It should also be pointed out that these methods have some technical problems as well. Experimental evidences indicate that the ME content of feedstuffs may be affected by breed, age, substitution level of basal diet, kind of basal diet, methods of chemical analysis and chemical composition of experimental diet. Standard procedures and technical advantages of newly developed method of "True Metabolizable Energy" system are fully described.

• Journal of Nutrition and Health
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• v.25 no.7
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• pp.543-554
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• 1992

True metabolizable energy(TME) is believed a better indicator for animal performance than apparent metabolizable energy (AME) for excluding the endogenous energy losses from excreta, However few researches have been conducted to compare superiority of any energy systems through practical animal feeding tests. Present study was to compare the energy systems in young chicks in terms of predictability of energy intake for the birds performances including body energy retention and of methodological accuracy by evaluating reproducibility and additi-vity of energy values of feed ingredients and compound diets. Five ingredients such as yellow corn wheat soybean meal fish meal and wheat bran were measured for their various biological energy values. in the first feeding trial chicks were restric-ted-fed the basal diet at 80, 60 and 40% on weight basis of the amount of feed ingested by chicks fed ad libitum the same diet. chicks in the second trial were also restricted-fed diets at levels of 80, 70, 60 and 50% on energy basis of the amount consumed by the basak duet group fed ad libitum The diets in the latter trial were however composed of differeent formulations from the basal diet. One-week-old Single Comb White Leghorn male chicks were individually alloted in a cage on 10 cages/treatment basis and fed the diets for 14 days. Individual carcass energy was measured after the feeding trials. Coefficients of variation of energy measurements were lesser for nitrogen-corrected AME and TME(AMEn & TMEn respectively) than AME and TME values suggesting taht reprodu-cibility of energy determinations by former systems could be better than the latters. The coeffi-cients for AME and TME were almkost of the same values. Additivity obtained by the rations between the calculated values and catual measurements appeared quite satisfactory for all the energy systems. Those of AME and TME however were relatively better than the other systems. Regression coefficient ${r}^2$ between energy intake by various systems and chick performances appeared higher for TME, AMEn and TMEn than AME implying that the former systems could provide better predictability for body weight gain and energy retention than the AME. The ${r}^2$ values for TME and AMEn particularly for body weight gain were on the average 0.967 and 0.960 respectively. In conclusion TME or AMEn can be recommended as choice for dietary energy system in terms of performance predictability of the birds and of procedural convenience for the measurements.

• Asian-Australasian Journal of Animal Sciences
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• v.26 no.6
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• pp.838-844
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• 2013

This study was conducted to evaluate chemical composition, nitrogen-corrected true metabolizable energy (TMEn) and true amino acids digestibility of corn distillers dried grains with solubles (DDGS) produced in China. Twenty five sources of corn DDGS was collected from 8 provinces of China. A precision-fed rooster assay was used to determine TMEn and amino acids digestibility with 35 adult cecectomized roosters, in which each DDGS sample was tube fed (30 g). The average content of ash, crude protein, total amino acid, ether extract, crude fiber and neutral detergent fiber were 4.81, 27.91, 22.51, 15.22, 6.35 and 37.58%, respectively. TMEn of DDGS ranged from 1,779 to 3,071 kcal/kg and averaged 2,517 kcal/kg. Coefficient of variation for non-amino acid crude protein, ether extract, crude fiber and TMEn were 55.0, 15.7, 15.9 and 17.1%, respectively. The average true amino acid digestibility was 77.32%. Stepwise regression analysis obtained the following equation: TMEn, kcal/kg = -2,995.6+0.88${\times}$gross energy+$49.63{\times}a^*$ (BIC = 248.8; RMSE = 190.8; p<0.01). Removing gross energy from the model obtained the following equation: TMEn, kcal/kg = 57.88${\times}$ether extracts+$87.62{\times}a^*$ (BIC = 254.3, RMSE = 223.5; p<0.01). No correlation was found between color scores and lysine true digestibility (p>0.05). These results suggest that corn DDGS produced in China has a large variation in chemical composition, and gross energy and $a^*$ value can be used to generate TMEn predict equation.

• Korean Journal of Poultry Science
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• v.31 no.4
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• pp.255-263
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• 2004

Two experiments were conducted to evaluate the feeding values of sesame oil meal (SOM) and to investigate the effects of its dietary supplementation on egg production in laying hens. In experiment I, the values of true metabolizable energy (TME), nitrogen corrected true metabolizable energy (TMEn) and true amino acid availability (TAAA) were determined by force-feeding 16 ISA-Brown roosters and collecting the total excreta from the birds, The TME and TMEn of SOM were 2.30 and 1.99 kcal/g, respectively, and the average TAAA of 15 amino acids was $76.93\%$. In experiment 2, a total of ninety, 48 weeks old ISA-Brown layer were randomly divided into 9 groups of 10 birds each and assigned to three experimental diets containing 0, 5 and $10\%$ SOM for 4 weeks (30 birds per treatment). The inclusion of SOM into laying hen diets at the 5 and $10\%$ level did not affect production and quality of egg. The C18:3 $\omega$3 content of egg yolks in the $10\%$ SOM group was higher than the other groups, but not significantly. There were no adverse effects on blood parameters in layers fed treated diets containing $5\%$ or $10\%$ SOM, The results indicate that SOM can be used for layers diet up to $10\%$ without any significant negative effects on egg production and quality.

• Korean Journal of Poultry Science
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• v.20 no.4
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• pp.189-196
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• 1993

True amino acid availability (TAAA) and true metabolizable energy(TME) values of 8 protein feedstuffs were determined by feeding three roosters exactly 30g of each protein feedstuff after 36h of fasting. From each rooster excreta were collected for 36 h. TAAA were significantly(P<0.01) different among protein feedstuffs. TAAA was highest in fish meal(96.1%), followed by corn gluten(91.2%), rapeseed meal(88.8%), soybean meal(88.7%), meat meal(87.2%), canola meal(86.1%), cottonseeed meal(82.6%) and feather meal(82.5%). Available Iysine values obtained by TAAA method were highly correlated(P<0.01) with those obtained by chick bioassay(CBA) and FDNB method. TME was highest in corn gluten(4,011kcal/kg, as fed basis), followed by fish meal(3,906), feather meal(3,098), soybean meal(3,007), meat and bone meal(2,631), canola meal(2,326), cottonseed meal(2,246) and rapeseed meal(2,120).